NL2001360C2 - MAGNETIC RESONANCE IMAGE DEVICE AND MAGNETIC RESONANCE IMAGE METHOD. - Google Patents

Description

P29252NL00 / GB / fhe

Brief indication: Magnetic resonance imaging device and magnetic resonance imaging method.

BACKGROUND OF THE INVENTION

The invention relates to a magnetic resonance imaging (MRI) device and a magnetic resonance imaging method. The invention relates in particular to a magnetic resonance imaging device and a magnetic resonance imaging method, each of which performs a mask scan for acquiring, as mask data, magnetic resonance signals produced in an imaging area of a subject, each of which has a perform an image scan for acquiring magnetic resonance signals produced in the image area as image data to correspond to a TRICKS (Time Resolved Imaging for Contrast KineticS) method, thereby sequentially images of the image area along a time base to generate.

The magnetic resonance imaging device was used in various fields such as a medical field, an industrial field, etc.

The magnetic resonance imaging device comprises an imaging space formed with a static magnetic field. A display area, which contains a target, for displaying a subject, is housed or held in the display space. Thus, proton spiders in the imaging area are placed in the direction in which the static magnetic field is formed to obtain magnetization vectors thereof. An RF pulse is then sent to the imaging area of the subject in the imaging space formed with the static magnetic field to generate a nuclear magnetic resonance (NMR) phenomenon, thereby rotating the magnetization vectors of the spiders. Next, magnetic resonance (MR) signals that are generated when the magnetization vectors of the rotated spiders have returned to an original direction of the static magnetic field are acquired. The subject is scanned according to, for example, a pulse sequence, such as a spin echo method, a gradient-recalled echo method, or the like. Next, image reconstruction processing is performed on magnetic resonance signals acquired by performing this scan to generate slice images of an image area of the subject.

In the magnetic resonance imaging device, blood imaging, called "MRA (MR angiography)," is performed to project or create a fluid, such as blood flowing through blood vessels. In this MRA, mapping is performed using an up-time (TOF) effect or a phase contrast (PC) effect or the like.

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As an imaging method for this MRA, a TRICKS method has been proposed (reference is made, for example, to Japanese Unexamined Patent Publication No. Hei 10 91998) -5191 and Japanese Unexamined Patent Publication No. 2006-122301. Since imaging in the present method can be performed by a simple operation and a high time resolution can be provided, any slice image can be obtained with suitable timing with respect to an imaging area into which a contrast agent has flowed. The TRICKS method is useful because any imaging area that contains portions that vary in time of arrival of the contrast agent and is difficult to determine an exact timing, such as in the case of peripheral blood vessels of lower limbs of a human and the like, can be displayed or photographed continuously in a short period of time.

In the TRICKS method, however, any magnetic signal acquired as mask data could be a high signal in any portion in which the fluid, such as blood, flows, due to the influence of an inflow effect upon acquisition of the mask data by the first Therefore, when image data of a mask image MG generated on the basis of such mask data is subtracted from image data of each image IG displayed, a portion into which the contrast agent flows cannot be generated with strong contrast in each different image SG. As a result, the image quality deteriorates and an efficient execution of an image diagnosis can become difficult.

20

SUMMARY OF THE INVENTION

It is desirable that the previously described problem be solved.

According to one aspect of the invention, a magnetic resonance imaging device is provided, which device performs a mask scan for acquiring magnetic resonance signals as mask data, which in an imaging area, in which a fluid flows through a subject in a state in which no contrast means has been injected into the fluid, produced and performs an imaging scan for acquiring magnetic resonance signals as imaging data which are in the imaging area into which the fluid containing the contrast agent flows after the injection of the contrast agent into the fluid produced to correspond to a TRICKS method, thereby sequentially generating images of the image area along a time base, which includes magnetic resonance imaging device: a scanning device that performs the mask scan and the image scan, wherein the scanning device performs the m bearer scan repeatedly performs scans for transmitting a spatial saturation pulse to a corresponding area containing the fluid flowing into the imaging area, and subsequently sequentially acquiring mask data from -3- the magnetic resonance signals as mask data to correspond thereto with respective segments that are divided into a k space in multiple form.

Preferably, the scanning device performs the mask scan in such a way that the directions of each magnetic tape acquisition sequence of the magnetic resonance signals with respect to the respective segments are aligned in directions opposite to each other through the center of the k space in the segments.

The scanning device preferably performs the mask scan in such a way that the acquisition directions are directed from the center of the k space to the periphery thereof.

Preferably, after transmitting the spatial saturation pulse, the scanning device further performs the mask scan to sequentially acquire the magnetic resonance signals as mask data at the end of each repeat time free of acquisition of the magnetic resonance signals as mask data.

When performing the mask scan, the scanning device preferably performs the scans in such a way that they correspond to respective segments divided into multiple forms, so as to be symmetrical with respect to an axis passing through the center of a k space .

When performing the mask scan, the scanning device preferably performs the scans in such a way that they correspond to respective segments divided into multiple forms, so as to be radially symmetrical from the center of a k space to the circumference thereof.

Preferably, the scanning device performs the mask scan prior to performing the image scan.

According to another aspect of the invention, a magnetic resonance imaging method is provided, which method performs a mask scan for acquiring magnetic resonance signals as mask data, which in an imaging area, in which a fluid flows through a subject in a state, in which no contrast agent is injected into the fluid, are produced and perform an imaging scan for acquiring magnetic resonance signals as imaging data, which flow into the imaging region, in which the contrast-containing fluid flows after the injection of the contrast agent into the fluid. fluid, to correspond to a TRICKS method, thereby sequentially generating images of the imaging area along a time basis, which magnetic resonance imaging method comprises the following step of repeatedly performing scans for the mask scan sending a hold saturation pulse to a corresponding region containing the fluid flowing in the imaging region 35, and subsequently sequentially acquiring, as a mask data, the magnetic resonance signals as mask data to correspond to respective segments which are in a k-space in multiple form divided.

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Preferably, the mask scan is performed in such a way that the directions of acquiring each magnetic resonance signal sequentially as mask data from the magnetic resonance signals with respect to the respective segments are directed in directions opposite to each other through the center of the k space in the segments.

The mask scan is preferably carried out in such a way that the directions of acquisition are directed from the center of the k space to the circumference thereof.

Preferably, after the transmission of the spatial saturation pulse, the scanning device further performs the mask scan to sequentially acquire the magnetic resonance signals as mask data after each repetition time after the lapse of each repeat time free of acquisition of the magnetic resonance signals as mask data.

When performing the mask scan, the scanning device preferably performs the scans in such a way that they correspond to respective segments divided into multiple forms so as to be symmetrical with respect to an axis passing through the center of a k space.

Preferably, when performing the mask scan, the scanning device performs the scans in such a way that they correspond to respective multi-segmented segments, so as to be radially symmetrical from the center of a k space to its periphery.

Preferably, the scanning device performs the mask scan prior to performing the image scan.

According to another aspect of the invention, a magnetic resonance imaging device is provided, which device performs a mask scan for acquiring magnetic resonance signals produced as a mask data in a imaging area of a subject, and performs an imaging scan for imaging data. acquiring magnetic resonance signals produced in the imaging area to correspond to a TRICKS method, thereby sequentially generating images of the imaging area along a time base, which includes magnetic resonance imaging device: a scanning device, which performs a mask scan and the imaging scan, wherein, when performing the mask scan, the scanning device repeatedly performs scans for sending a preparation pulse to the subject and then sequentially acquiring the magnetic resonance signals as mask data every repetition time, to correspond to respective k-space segments divided into multiple form.

Preferably, the scanning device performs the mask scan in such a way that the directions of acquiring the magnetic resonance signals sequentially as mask data for each repetition time with respect to the respective segments are directed in directions opposite to each other through the center of the k space in the segments.

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The scanning device preferably performs the mask scan in such a way that the acquisition directions are directed from the center of the k space to the periphery thereof.

Preferably, a magnetic resonance imaging method is provided that performs a mask scan for acquiring magnetic resonance signals as a mask data produced in an imaging area of a subject and performing an imaging scan for acquiring magnetic imaging data as imaging data resonance signals produced in the imaging area to correspond to a TRICKS method, thereby sequentially generating images of the imaging area along a time basis, which magnetic resonance imaging method comprises the following step: of the mask scan repeatedly performing scans for sending a preparation pulse to the subject and then sequentially acquiring the magnetic resonance signals as mask data each repetition time to correspond to respective k-space segments divided into multiple forms.

Preferably, the scanning device performs the mask scan in such a way that the directions of acquiring the magnetic resonance signals sequentially as mask data for each repetition time with respect to the respective segments are directed in directions opposite to each other through the center of the k space in the segments.

The scanning device preferably performs the mask scan in such a way that the acquisition directions are directed from the center of the k space to the periphery thereof. According to the invention, a magnetic resonance imaging device and a magnetic resonance imaging method can be provided, which are capable of improving image quality and performing an image diagnosis efficiently.

Further objects and advantages of the invention will become apparent from the following description of the preferred embodiments of the invention, as shown in the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a configuration diagram showing a construction of a magnetic resonance imaging device 1 illustrative of a first embodiment of the invention.

FIG. 2 is a flow chart showing the operation performed when a subject SU is displayed or photographed in the first embodiment of the invention.

FIG. 3 is a diagram showing the manner in which an image area of a subject is scanned by a TRICKS method in the first embodiment of the invention, wherein the horizontal axis is a time base.

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FIG. 4 is a diagram showing a k-space in which magnetic resonance signals are acquired or collected by performing a mask scan MS in the first embodiment of the invention.

FIG. 5 is a pulse sequence diagram at the time when mask data is acquired in each segment when performing the mask scan MS in the first embodiment of the invention.

FIG. 6 is a diagram showing a sequence at the time mask data is acquired with respect to matrices forming segments when performing the mask scan MS in the first embodiment of the invention.

FIG. 7 is a diagram showing a k-space in which magnetic resonance signals are acquired when performing an image scan IS in the first embodiment of the invention.

FIG. 8 is a pulse sequence at the time when image data is acquired in each segment area when performing the image scan IS in the first embodiment of the invention.

FIG. 9 is a flow chart showing the operation of sequentially generating images from an image area along a time axis in the first embodiment of the invention.

FIG. 10 is a diagram showing the manner in which a mask image MG is generated in the first embodiment of the invention.

FIG. 11 is a diagram showing the manner in which each image image IG is generated in the first embodiment of the invention.

FIG. 12 is a diagram showing the manner in which each difference image SG is generated in the first embodiment of the invention.

FIG. 13 is a diagram showing a k space in which magnetic resonance signals are acquired when performing a mask scan MS in a second embodiment of the invention.

FIG. 14 is a diagram showing a k-space in which magnetic resonance signals are acquired when performing a mask scan MS in a third embodiment of the invention.

FIG. 15 is a diagram showing a sequence at the time mask data is acquired with respect to matrices forming segments when performing the mask scan MS in the fourth embodiment of the invention.

FIG. 16 is a diagram showing a sequence at the time mask data is acquired with respect to matrices forming segments when performing the mask scan MS in the fifth embodiment of the invention.

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DETAILED DESCRIPTION OF THE INVENTION

One example of an embodiment of the invention will be explained below with reference to the accompanying drawings.

5 <First embodiment »

FIG. 1 is a configuration diagram showing an overview of a construction of a magnetic resonance imaging device 1 illustrative of a first embodiment of the invention.

10 <assembly structure>

FIG. 1 is a configuration diagram showing the construction of the magnetic resonance imaging device 1 illustrative of the first embodiment of the invention.

As shown in FIG. 1, the magnetic resonance imaging device 1 has a scanning section 2 and a processing console section 3.

The scanning section 2 has a static magnetic field magnet unit 12, a gradient coil unit 13, an RF coil unit or portion 14, a carrier device 15, an RF driver unit 22, a gradient driver unit 23, and a data acquisition unit 24, as shown in FIG. 1. As shown in Fig. 1, the processing console section 3 has a control unit 30, an image reconstruction unit 31, an operating unit, a display or display unit 33, and a storage unit 34.

In the present embodiment, the magnetic resonance imaging device 1 performs each scan on an imaging area of a subject to correspond to a TRICKS method, thereby sequentially generating images of the imaging area along a time basis. That is, a mask scan for collecting or acquiring magnetic resonance signals produced as a mask data in a imaging area in which a fluid, such as blood, flows through a subject SU in a state in which no contrast agent is injected into the fluid. , and an imaging scan for acquiring magnetic resonance signals produced as imaging data in the imaging area, into which a fluid containing the contrast agent flows after the injection of the contrast agent into the fluid, such as blood, are performed based on the TRICKS method to thereby generate images of the image area sequentially.

The scan section 2 will be explained.

As shown in FIG. 1, the scanning section 2 is provided with an imaging space B, which is formed with a static magnetic field, and in which a target imaging area for imaging the subject SU is housed or retained. The scanning section 2 applies RF pulses to the imaging area of the subject SU recorded in the imaging space B, -8- formed with the static magnetic field on the basis of a control signal output from the processing console section 3 to produce magnetic resonance signals of the magnetic resonance signals of the image area, wherein a scan for the image area of the subject SU is performed.

In the present embodiment, the scan section 2 performs the mask scan and the image scan to correspond to the TRICKS method. That is, the scan section 2 performs the mask scan to acquire the magnetic resonance signals produced in the imaging area in which the fluid such as blood flows into the subject SU as mask data in the state in which no contrast agent is injected into the fluid.

The scan section 2 performs the imaging scan after the contrast agent has been injected into the fluid flowing through the subject, to thereby acquire the magnetic resonance signals produced in the imaging area into which the fluid containing the contrast agent flows.

Although the details of the scan section 2 will be described later, the scan section 2 performs a scan for sending each spatial saturation pulse to an area containing at least one fluid flowing in an imaging area when performing the mask scan and subsequently sequentially acquiring magnetic resonance signals each repetition time. That is, the scan section 2 sends the spatial saturation pulse to the area in which the fluid flowing in the imaging area is present. This scan is then repeatedly performed to correspond to respective k-space segments divided into multiple forms. For example, this scan is performed on the respective multi-segmented segments to be symmetrical with respect to an axis passing through the center of the k space. The scan section 2 here performs the mask scan between the number of segments in such a way that the directions of acquiring each repetition time TR sequentially as mask data from magnetic resonance signals of these segments are directed in the directions opposite to each other with respect to the center of the k space. Described in particular, the scan section 2 performs the mask scan in such a way that the above acquisition directions are directed to the periphery, viewed from the center of the k space.

Respective constituent elements of the scan section 2 will be described in succession.

The magnet unit 12 for a static magnetic field is, for example, of a horizontal magnetic field type. A superconducting magnet (not shown) forms a static magnetic field along the direction (z direction) of a body axis of the subject SU, which is placed in an imaging space B in which the subject SU is received or held. Incidentally, the static magnetic field magnet unit may be of a vertical magnetic field type other than the horizontal magnetic field type, which forms a static magnetic field along the direction in which a pair of permanent magnets face each other.

The gradient coil unit 13 forms a magnetic gradient field by transmitting each gradient pulse to the imaging space B formed with the static magnetic field and adds spatial position information to each magnetic resonance signal received by the RF coil unit 14. The gradient coil unit 13 here comprises three systems which are set around a magnetic gradient field in relation to three axis directions, a z-direction, which extends along a direction of the static magnetic field, an x-direction and a y-direction, which is perpendicular on top of each other. These transmit gradient pulses in a frequency coding direction, a phase coding direction and a slice coding direction based on a control signal output from the control unit 30 to thereby form magnetic gradient fields. Described in particular, the gradient coil unit 13 provides the gradient magnetic field in the slice selection direction of the subject SU and selects each slice of the subject SU excited by transmitting an RF pulse through the RF coil unit 14. The gradient coil unit 13 supplies the gradient magnetic field in the phase encoding direction of the subject SU and phase-encodes a magnetic resonance signal from the slice excited by the RF pulse. The gradient coil unit 13 supplies the gradient magnetic field in the frequency encoding direction of the subject SU and frequency encodes the magnetic resonance signal from the slice excited by the RF pulse.

As shown in FIG. 1, the RF coil unit 14 is arranged around the subject SU

to surround. The RF coil unit 14 transmits an RF pulse corresponding to an electromagnetic wave to the subject SU within the imaging space B formed with the static magnetic field supplied by the magnet unit 12 based on a output from the control unit 30 control signal to thereby form a high-frequency magnetic field. Thus, magnetization vectors based on the proton spiders in the imaging area of the subject SU are rotated. Furthermore, the RF coil unit 14 receives an electromagnetic wave which is generated when each rotated magnetization vector in the imaging area of the subject SU returns to the original magnetization vector as a magnetic resonance signal.

The support device 15 is a table with a horizontal surface on which the subject SU is placed. The carrier device 15 is moved between the inside and outside of the display space B on the basis of a control signal supplied by the control unit 30.

The RF driver unit 22 drives the RF coil unit 14 to send an RF pulse to the imaging space B, thereby forming a high-frequency magnetic field in the imaging space B. The RF control unit 22 modulates a signal transmitted by an RF oscillator into a signal with a predetermined timing and a predetermined envelope using a gate modulator based on the control signal output from the control unit 30. Thereafter, the RF driver unit 22 allows an RF power amplifier to amplify the signal modulated by the gate modulator and outputs the amplified signal to the RF coil unit 14 and the RF coil unit 14 allows the corresponding RF pulse to be turned off. to send.

The gradient control unit 23 allows the gradient coil unit 13 to provide a gradient pulse based on the control signal output from the control unit 30 to thereby generate a magnetic gradient field within the imaging space B formed with the static magnetic field. The gradient control unit 23 has a three-system driver circuit (not shown) in relation to the three-system gradient coil unit 13.

The data acquisition unit 24 acquires each magnetic resonance signal received by the RF coil unit 14 based on the control signal output from the control unit 30. The data acquisition unit 24 phase detects the magnetic resonance signal received by the RF coil unit 14 using a phase detector, the output signal of the RF oscillator of the RF control unit 22 being used as a reference signal. Thereafter, the data acquisition unit 24 converts the magnetic resonance signal corresponding to the analog signal to a digital signal by using an A / D converter and outputs the digital signal.

The operation console section 3 will be explained.

The processing console section 3 controls the scan section 2 such that the scan section 2 performs a scan for the subject, and generates each image of the subject based on the magnetic resonance signal obtained by the scan performed by the scan section 2, and displays the generated image.

Respective parts, which form the processing console section 3, will be described one after the other.

The control unit 30 has a computer memory, which stores programs, which programs enable the computer to perform predetermined data processing, and controls respective components. The control unit 30 inputs processing data sent by the control unit 32 and controls the scanning section 2 on the basis of the processing data entered by the control unit 32. As shown in FIG. 1, this means that the control unit 30 outputs control signals to the RF control unit 22, the gradient control unit 23 and the data acquisition unit 24 and that the control unit 30 thereby controls the operations of the respective components to correspond to the set scan conditions. Together with this, the control unit 30 outputs control signals 35 to the data processor 31, the display unit 33, and the storage unit 34 to perform control thereof.

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The image reconstruction unit 31 has a computer and a memory which stores therein programs for performing predetermined data processing using the computer. The image reconstruction unit 31 performs image reconstruction processing based on the control signal supplied by the control unit 30 to reconstruct each image. The magnetic resonance signals acquired to correspond to the k-space by performing the scan for the subject's image region by means of the scan section 2 are subjected to a Fourier transform process, thereby completing the image reconstruction process wherein each image of the imaging area is reconstructed. In addition, the image reconstruction unit 31 outputs data 10 from each reconstructed image to the display unit 33.

In the present embodiment, the image reconstruction unit 31 performs the mask scan and the image scan in such a way that they correspond to the TRICKS method and successively generate the images of the image area along the time base based on the mask data as and imaging data acquired magnetic resonance signals.

The operating unit 32 is formed by an operating device, such as a keyboard, a pointing device or the like. The operating unit 32 enters processing data from an operator and outputs it to the control unit 30.

The display unit 33 is formed by a display device, such as a CRT, and displays each image on its display screen on the basis of the control signal output from the control unit 30. For example, the display unit 33 displays images of input items which correspond to the processing data entered by the operator in the operating unit 32 on the display screen in multiple form. Furthermore, the display unit 33 receives data on each image for the display area, which image has been reconstructed by the image reconstruction unit 31, and the display unit 33 displays the image on the display screen.

The storage unit 34 includes a storage device, such as a memory, and stores various data therein. The data stored in the storage unit 34 can be accessed by the control unit 30 if desired.

30 <Working>

The operation of imaging the subject SU will be explained below using the magnetic resonance imaging device 1, which is illustrative of the present embodiment referred to above.

FIG. 2 is a flow chart showing the operation of the first embodiment of the invention at the time the subject SU is displayed or photographed.

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FIG. 3 is a diagram showing the manner in which an image area of a subject is scanned by the TRICKS method in the first embodiment of the invention. In fig. 3 the time base is indicated in the form of the horizontal axis.

As shown in Fig. 2, a mask scan MS is first performed (S11).

The scan section 2 performs the mask scan MS in such a way to acquire magnetic resonance signals as mask data, which magnetic resonance data are produced in an imaging area, in which a fluid, such as blood, flows into or through the subject SU with respect to respective matrices in a k space in a state in which no contrast agent is injected into the fluid.

Described in particular and as shown in Fig. 3, scans S for acquiring magnetic resonance signals sequentially every repetition time TR as mask data are performed sequentially during a mask scan execution period MT in each segment area A1, ..., A4, B1 ,. ... B4, C1 ..... C4 and D1, ..., D4, divided to contain a number of matrices in a k space. For example, as shown in FIG. 3, the scans 15 are repeatedly performed to correspond to the respective segments of k space, divided into 16 segment regions A1, .... A4, B1, ..., B4, C1 ... ..C4 and D1, ..., D4.

FIG. 4 is a diagram showing a k space in which magnetic resonance signals are acquired by performing a mask scan MS in the first embodiment of the invention.

In the present embodiment, as shown in Fig. 4, a k-space ks is divided into a number of segment areas A1, .... A4, B1, ..., B4, C1, ..., 04 and D1 , ..., D4. The k-space ks is here divided into the number of segment areas A1, ..., A4, B1, ..., B4, C1, ..., C4 and D1 ..... D4 so as to be symmetrical with respect to the center of the k-space to be ks. The number of divisions in the segment areas is set based on a command entered by an operator. The command is entered by the operator considering saturation effects of spatial saturation pulses and an influence on the display time, which will be described later. The command can be set automatically so that the spatial saturation pulses are delivered at predefined intervals. With a three-dimensional k-space ks, which is defined for example by three axes, a kx-axis, a ky-axis and a kz-axis, the k-space is divided in two as seen in a ky-axis direction and divided into eight, viewed in a kz-axis direction, as shown in Fig. 4.

As a result, the k space is divided in total into 16 segment areas A1, ..., A4, B1, ... B4, C1, ..., C4 and D1, ..., D4. This means that the k-space ks is divided into the first to sixteenth segment areas A1, ..., A4, B1 ..... B4, C1 ..... C4 and D1, ..., D4, dependent on a kx-ky plane and a kx-kz plane, so as to be symmetrical with respect to the center of the k-space ks, viewed in the ky-axis direction, and to be symmetrical with respect to the center of the k space ks, viewed in the kz axis direction. Described in particular and as shown in FIG. 4, four regions An, Bn, Cn and Dn are divided into two equal parts in the ky-axis direction and kz-axis direction, respectively divided into four equal parts in the kz-axis direction, whereby the k-space ks is divided into the sixteen segment areas A1, .... A4, B1, ..., B4, C1, ..., C4 and D1, .... D4. Thus, in the present embodiment, the segments are distributed in such a way that distributions of respective points in the segments are equal to each other, even in any segment from the center of the k space to the peripheral portion thereof.

As shown in Fig. 3, the scans S are performed sequentially in segment area units to correspond to the respective segments. The scans S are performed sequentially with respect to the respective segments, such as in the case of, for example, A1, B1, A2, B2, A3, B3, A4, B4, C1, D1, C2, D2, C3, D3, C4 and D4.

As shown in FIG. 4, the scans are performed in such a way that the directions DR of the magnetic resonance signals sequentially acquiring the magnetic resonance signals every repetition time TR to correspond to the respective matrices in the segment regions A1, ... .4, A4, B1, ..., B4, C1, .... C4 and D1 ..... D4, are directed in the directions opposite to each other between the segment regions, which are symmetrical with respect to the center of the k space are ks. As shown in FIG. 4, the scans are carried out by way of example in such a way that the acquisition directions DR are oriented circumferentially along the ky axis direction, viewed from the center of the k space ks. As shown in Fig. 4, this means that the scans are performed on the segment areas B1, B2, B3, B4, D1, D2, D3 and D4 adjacent to the segment areas A1, A2, A3, A4, C1, C2, C3 and C4 via the kx-kz plane in such a way that the acquisition direction DR is directed in the opposite direction.

FIG. 5 is a pulse sequence diagram at the time that mask data is acquired with respect to respective segments when performing a mask scan MS in the first embodiment of the invention. FIG. 5 shows an RF pulse RF, a gradient pulse Gs in a slice selection direction, a gradient pulse Gp in a phase encoding direction perpendicular to the slice selection direction, and a gradient pulse Gr in a frequency encoding direction perpendicular to the slice selection direction and the phase encoding direction. Incidentally, the vertical axis indicates strength and the horizontal axis indicates time in the present embodiment.

FIG. 6 is a diagram showing a sequence as mask data is acquired with respect to matrices forming segments when performing the mask scan MS in the first embodiment of the invention.

In the present embodiment, as shown in FIG. 5, a spatial saturation pulse SAT is first sent to each region that contains a fluid flowing in the corresponding imaging region. For example, a 100 ° pulse and a spoiler pulse are used as spatial saturation pulses to allow horizontal magnetization to disappear. Thereafter, each repetition time TR sequentially magnetic resonance signals are acquired as mask data with a pulse sequence GR corresponding to, for example, the first gradient echo method. Described in particular, a ° pulses together with a slice selection gradient pulse are transmitted in such a way that magnetization moments of spiders in the imaging areas are rotated through rotation angles of 5 ° to thereby selectively excite the imaging areas. Next, a gradient pulse for phase encoding is transmitted in each of the slice selection and phase encoding directions. This means that, to effect imaging or photographing of a three-dimensional imaging area, a gradient pulse for performing phase coding in the slice selection direction is also transmitted in such a way that mask data corresponding to a three-dimensional k space is acquired. A gradient pulse is then transmitted in the frequency coding direction to sample the magnetic resonance signals. Thereafter, a spoiler pulse to allow horizontal magnetization to disappear is transmitted in the frequency encoding direction and a gradient rewinding pulse is transmitted in each of the slice selection direction and the phase encoding direction. The sampling of the magnetic resonance signals is hereby performed while the phase coding is changed step by step every repetition time TR. The number of mask data is thus acquired after the transmission of one spatial saturation pulse SAT.

As shown by way of example in Fig. 6, 128 mask data is acquired sequentially each repetition time TR from the side of the center of the k-space ks 20 to the peripheral side thereof in the segment region A1. Similarly, 128 mask data is acquired sequentially from the side of the center of the k space ks to the peripheral side thereof, even in other segment regions.

Next, an image scan IS is performed, as shown in Fig. 2 (S21).

As shown in FIG. 3, a contrast agent is hereby injected into the fluid flow in the subject SU during a temporary stopping period PT following the expiration of the mask scan execution period MT. Thereafter, the scan section 2 performs the image scan IS during an image scan execution period IT to collect or acquire produced magnetic resonance signals as image data in an image area in which the fluid containing the contrast medium flows.

Described in particular and as shown in Fig. 3, magnetic resonance signals are acquired sequentially every repetition time TR as imaging data to correspond to the respective segments of the k-space, for example divided into four of first, second, third and fourth segment regions A , B, C and D.

FIG. 7 is a diagram showing a k-space in which magnetic resonance signals are acquired upon performing an image scan IS in the first embodiment of the invention.

In the present embodiment shown in Fig. 7, the k-space ks is divided into a number of segments A, B, C and D from a low-frequency region located in the middle thereof to a high-frequency region located at its periphery. frequency range. For example, the first segment area A is divided into the k space ks to correspond to a central area that includes the center along a kx axis direction. The second segment area B, the third segment area C and the fourth segment area D are divided stepwise to extend from the first segment area A to the circumference of the k space. As shown in Fig. 7, the first segment region A is divided here to achieve a cylindrical shape, the kx axis direction passing through the center of the k space ks as an axis. The second segment region B 10 is divided to cover the circumference of the first segment region A in the form of a cylinder with the kx axis direction passing through the center of the k space ks. The third segment region C is then divided to cover the circumference of the second segment region B in the form of a cylinder with the kx axis direction passing through the center of the k space ks. Furthermore, the fourth segment area D is divided to cover the circumference of the third segment area C in the k space ks.

Magnetic resonance signals are acquired with respect to the respective segment areas A, B, C and D.

In contrast to the mask scan MS, as shown in Fig. 3, here a first scan S1 for acquiring a magnetic resonance signal corresponding to the first segment region A, which first segment region is placed around the center of the k space, and a second scan S2 for acquiring a magnetic resonance signal corresponding to each of other second, third and fourth segment regions B, C and D, repeatedly performed alternately. With respect to the second scans S2, the magnetic resonance signals corresponding to the second, third and fourth segment regions B, C and D, which are multiple segment regions divided into the k-space in the first segment region A, are sequentially acquired in segment region units to insert the execution of the number of first scans S1 between the second scans S2. That is, after the magnetic resonance signals, each corresponding to the second segment area B, are acquired when performing the second scans S2, magnetic resonance signals, each corresponding to the third segment area C, that one of the second segment area B is different segment area are acquired through performing the first scans S1. After the magnetic resonance signals, each corresponding to the third segment area C, are acquired in performing the second scans S2, magnetic resonance signals each corresponding to the fourth segment area D becomes one of the second segment area and the third segment area is different segment area acquired through performing the first scans S1.

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Described in particular, when performing the image scan IS, as shown in FIG. 3, the magnetic resonance signals corresponding to the segments are acquired in a sequence, such as in the case of the first segment area A, the second segment area B , the first segment area A, the third segment area C, the first segment area A, the fourth segment area D, the first segment area A, ... When performing the imaging scan IS, the magnetic resonance signals corresponding to the first segment regions A, which are arranged to contain the center of the k-space ks, thus acquired to a greater extent than the magnetic resonance signals corresponding to other second, third and fourth segment regions B, C and D, which are around 10 k space ks are located.

However, upon completion of the image scan IS, as shown in Fig. 3, the scans are performed in the order of the second segment area B, the third segment area C and the fourth segment area D from the first segment area A to the periphery in a manner similar to the related technique without repeating the first scan S1 and the second scan S2 alternately.

As shown in FIG. 7, the scan is performed in such a way that the direction DR of the magnetic resonance signals sequentially acquiring the magnetic resonance signals every repetition time TR as image data in the first, second, third and fourth segment areas A, B, C and D is directed from the center of the k space to its circumference.

FIG. 8 is a pulse sequence at the time that image data in each segment area is acquired when performing the image scan IS in the first embodiment of the invention. FIG. 8 shows an RF pulse RF, a gradient pulse Gs in a slice selection direction, a gradient pulse Gp in a phase encoding direction perpendicular to the slice selection direction, and a gradient pulse Gr in a frequency encoding direction perpendicular to the slice selection direction and the phase encoding direction. Incidentally, the vertical axis indicates strength and the horizontal axis indicates time in the present embodiment,

The spatial saturation pulse SAT is not sent to the area containing the fluid flowing through each imaging area, as opposed to the case (see FIG. 5) of the mask scan MS, in the present embodiment shown in FIG. 8 . However, every repetition time TR magnetic resonance signals are sequentially acquired as image data according to the pulse sequence corresponding to the first gradient echo method, in a manner similar to the mask scan MS. Here, the repeat time TR in the image scan IS is set to be equal to the repeat time TR in the mask scan MS, and the corresponding scan is performed.

Next, the generation of each image is performed as shown in FIG. 2 (S31).

-17-

Here, the mask scan MS and the image scan IS are performed to correspond to the TRICKS method, as mentioned above. Therefore, based on magnetic resonance signals acquired as mask data and image data, the image reconstruction unit 31 sequentially generates images of an image area along the time base.

In the present embodiment, a mask image is image-reconstructed based on the mask data and an image image is image-reconstructed based on the image data. Thereafter, each difference image is generated by subtracting data from the image image from data from the mask image.

FIG. 9 is a flow chart showing the operation of sequentially generating images from an image area along a time base in the first embodiment of the invention.

As shown in FIG. 9, a mask image MG is first generated (S311).

FIG. 10 is a diagram showing the manner in which a mask image MG is generated in the first embodiment of the invention.

As shown in FIG. 10, the mask image MG is hereby image reconstructed using mask data acquired or collected to correspond to sixteen segment areas when performing a mask scan MS.

Next, image images IG are generated, as shown in Fig. 9 (S321).

FIG. 11 is a diagram showing the manner in which image images IG are generated in the first embodiment of the invention.

In the present embodiment, as shown in Fig. 11, the image images IG are sequentially image-reconstructed along a time base t. That is, the image images IG are sequentially image reconstructed along the time base t to correspond to time phases in which first and second scans S1 and S2 are performed as an image scan IS.

When, in particular, the first and second scans S1 and S2 are performed sequentially as the image scan IS, as in the case of a first time phase t1, ..., an eighth time phase t8, ..., and a twelfth 11, a first image image IG1, .... an eighth image image IG8, a twelfth image image IG12, ... sequentially image-reconstructed with respect to the first time phase t1. ., eighth time phase t8, ..., twelfth time phase t12 .....

For example, in generating the first image image IG1, as shown in FIG. 11, a magnetic resonance signal acquired to correspond to a first segment area A is acquired by performing the first scan S1 in the first time phase t1, and magnetic resonance signals acquired by means of scans performed to correspond to second, third and fourth segment areas B, C and D other than the first segment area A before and after performing the first scan S1. That is, magnetic resonance signals corresponding to segments other than a segment acquired by each scan performed in a predetermined time phase are interpolated by a magnetic resonance signal acquired by a scan performed in a different time phase. At this time, if the scans S corresponding to the other first and second scans S1 and S2 in the image scan IS have not been performed and the scans S in the mask scan MS are performed prior to performing the first scan S1 in the first time phase t1, 10 as shown in FIG. 11, mask data of portions corresponding to the second, third, and fourth segment regions B, C, and D, respectively, in the k space ks, in which the image data is acquired, as shown in FIG. 7, is used. in a k space ks, in which mask data is acquired as indicated by dashed lines in FIG. 11.

As shown in Fig. 11, this means that the magnetic resonance signal acquired as the image data in the first time phase t1 is used in the first segment area A. The magnetic resonance signal acquired as mask data to correspond to the second segment area B in the mask scan MS, and the magnetic resonance signal acquired as image data in the second time phase t2 in the image scan IS is used in the second segment region B. Here, for example, the average value of both is used. Similarly, the magnetic resonance signal acquired as mask data to correspond to the third segment area C in the mask scan MS, and the magnetic resonance signal acquired as image data in the fourth time phase t4 in the image scan IS are used in the third segment area C Similarly, the magnetic resonance signal acquired as mask data to correspond to the fourth segment area D in the mask scan MS, and the magnetic resonance signal acquired as image data in the sixth time phase t6 in the image scan IS are used in the fourth segment area D.

In the execution of the eighth image image IG8, as shown, for example, in FIG. 11, the magnetic resonance signal acquired to correspond to the second segment area B is performed by performing the second scan S2 in the eighth time phase t8, and the magnetic resonance signals acquired by the scans performed to correspond to the first, third, and fourth segment regions A, C, and D other than the second segment region B are used before and after the second scan S2, respectively.

That is, as shown in FIG. 11, the magnetic resonance signal acquired as image data in the eighth time phase t8 is used in the second segment region B. In a similar manner as above, the magnetic resonance signal acquired as image data in the seventh time phase t7 and the magnetic resonance signal acquired as the image data in the ninth time phase t9 are respectively used in the first segment region A. the magnetic resonance signal acquired as image data in the fourth time phase t4 and the magnetic resonance signal acquired as image data in the tenth time phase t10 are respectively used in the third segment region C. The magnetic resonance signal acquired as image data in the sixth time phase t6 and the image data acquired as image data magnetic resonance signal acquired in the twelfth time phase t12 is used respectively in the fourth segment region D.

Next, a difference image SG is generated, as shown in Fig. 9 (S331).

FIG. 12 is a diagram showing the manner in which each difference image SG is generated in the first embodiment of the invention.

As shown in Fig. 12, here the image data of each mask image 15 MG is subtracted from each of the image data of the image images IG generated along a time base t to generate a difference image SG as described above.

For example, the image data of the mask image MG is subtracted from the image data of a first image image IG1, which is generated to correspond to the first time phase t1, to generate a first difference image SG1. Similarly, a second difference image SG2, an eighth difference image SG8, ... are sequentially generated to correspond to the respective time phases t2, ..., t8, ...

Since, as described above, the difference image SG is obtained by subtracting the mask image MG from the image area, which is free from inflow of the contrast medium, from the image image IG from the image area, into which the contrast medium flows, each portion becomes , into which the contrast medium flows, generated as an image with a strong contrast.

In performing the mask scan MS in the present embodiment, as described above, the scans for transmitting the spatial saturation pulse SAT to each area containing the fluid flowing in the corresponding imaging area, and for the subsequent each repetition time TR sequentially acquiring the magnetic resonance signals as mask data successively executed repeatedly by means of the first gradient echo method to correspond to the segment areas A1, ..., A4, B1, .... B4, C1, ... C4, and D1, ..., D4, distributed in multiple form in the k space. Therefore, transmitting the spatial saturation pulse makes it possible to suppress that any magnetic resonance signal acquired as mask data from each vascular portion through which the fluid, such as blood, flows, is brought to a high signal due to the influence of an inflow effect on acquisition of the mask data. Thus, when the image data of the mask image MG generated on the basis of the mask data is subtracted from the image data of the image image IG, a portion into which the contrast means flows is generated with a strong contrast in each difference image SG. Since the vascular portion, which has hitherto been brought into the mask image due to the inflow effect, can be confirmed in the difference image SG, it has become easy to change the positions of the blood vessel regardless of the presence or absence of the contrast medium. When the spatial saturation pulse SAT is sent every repetition time TR, the total scan time thereby increases. However, since the mask data is transmitted during multiple repeat times TR after the transmission of the spatial saturation pulse SAT in the present embodiment, it is possible to suppress an increase in the scanning time.

In the present embodiment, the segments are further divided to separate them from each other in the k space, in which the image data is acquired in the image scan IS, and in the k space, in which the mask data is acquired in the mask scan MS. make differences. The k space in which the mask data is acquired in the mask scan MS is divided into several segments so that they are symmetrical with respect to the center thereof.

Since the application of the spatial saturation pulse SAT in the mask scan MS can be performed regardless of the data acquisition method in the image scan IS, therefore, the method of applying the spatial saturation pulse in the mask scan MS can be set freely.

When performing the mask scan MS in the present embodiment, the mask scan MS is performed in such a way that the directions DR of the acquisition of the magnetic resonance signals 25 with respect to the respective segments are sequentially acquired as mask data with respect to the respective segments. opposite directions through the center of the k space.

As a result, the influence of the spatial saturation pulse SAT is gradual throughout the k space. Described in particular, a successively obtained signal strength changes with the influence of the application of the spatial saturation pulse SAT. This change increases immediately after the application of the spatial saturation pulse SAT and then converges to a stable signal strength. Since the data is acquired from the center of the k space to the peripheral portion thereof after applying the spatial saturation pulses SAT in all segments, a change in signal due to the spatial saturation pulse SAT becomes large in the center of the k space and small 35 out there in any segment. Since the segments are laid out in such a way that they are symmetrically located around the center of the k space, the magnitude of the change in signal throughout the k space gradually changes from the center of the k space to the outside to. Therefore, the signal changes gradually over all segments compared to the case where the spatial saturation pulse is applied without examining the segments, and the change in signal with its application is spread over the entire k-space, thereby producing the effect that deterioration in image quality with signal change thereof can be suppressed to a minimum.

Also, in the present embodiment, the saturation effect of each spatial saturation pulse SAT can be enhanced. Described in particular, the saturation effect of the spatial saturation pulse SAT is increased immediately after its application and then becomes weak. Since the data is acquired from the center of the k space 10 to the peripheral portion thereof after the application of the spatial saturation pulses SAT to all segments, the saturation effect of the spatial saturation pulse SAT becomes strong at the center of the k space and weak outside it in any segment. Since the segments are explained to be symmetrical with respect to the center of the k space, the effect that the saturation effect of the spatial saturation pulse SAT becomes strong at the center of the k space, where the contrast is determined, and the effect that the spatial saturation pulse SAT can be amplified in the mask image MG produced in comparison with the case where the data acquired immediately after the application of the spatial saturation pulse SAT is spread over the entire k space.

The present embodiment is thus able to improve image quality and to make it easy to perform an image diagnosis efficiently.

<Second embodiment>

A second embodiment of the invention will be explained below.

The present embodiment differs from the first embodiment in terms of segment distribution method in the acquisition of magnetic resonance signals in a k space ks. With the exception of this point, the present embodiment is similar to the first embodiment. Therefore, the description of the same parts will be omitted.

FIG. 13 is a diagram showing a k space in which magnetic resonance signals are acquired by performing a mask scan MS in the second embodiment of the invention.

In the present embodiment shown in Fig. 13, a three-dimensional k-space ks defined by three axes, a kx-axis, a ky-axis and a kz-axis is divided into two, as seen in a kz-axis direction and divided into 256, seen in a ky direction. The k-space ks is thus divided into 512 segment regions A1, ..., A128, B1, ..., B128, C1, ..., C128, and D1, ..., D128. As shown in Fig. 13, this means that four regions An, Bn, Cn and Dn divided in the ky-axis direction and the kz-axis direction respectively are divided into 128 equal parts in the ky-axis direction, so that the k-space ks is divided into the 512 segment regions A1, ..., -22- A128, B1, ..., B128, C1, .... C128, and D1 ..... D128. The mask scan is performed in such a way that the directions DR, in which the magnetic resonance signals sequentially transmit each repetition time TR in the segment regions A1, .... A128, B1, .... B128, C1 .....

C128, and D1, .... D128 when mask data is acquired are directed in the opposite directions through the center of the k-space ks. As shown in FIG. 13, here the mask scan is performed in such a way that the acquisition directions DR are directed along the kz direction towards the circumference of the k space, seen from the center of the k space ks. As shown in Fig. 13, this means that the mask scan is performed in such a way on the segment areas A1, ..., A128 and B1 ..... B128 and the segment areas C1, ..., C128 and D1, .... D128, which are adjacent to each other via a kx-ky plane, that the acquisition directions DR are directed in opposite directions. For example, scans S are performed sequentially with respect to respective segments, such as in the order A1, C1, A2, C2, ... B127, D127, B128 and D128.

Using mask data acquired by performing the mask scan MS in this manner, difference images SG are generated in a manner similar to that of the first embodiment.

Since in the above-described present embodiment the mask scan MS is performed in a manner similar to that of the first embodiment, the image quality can be improved and an efficient execution of an image diagnosis can be facilitated.

<Third embodiment ^

A third embodiment of the invention will be explained below.

The present embodiment differs from the first embodiment in terms of segment distribution method at the moment that magnetic resonance signals are acquired in a k space ks when performing a mask scan MS. With the exception of this point, the present embodiment is similar to the first embodiment. Therefore, the description of equal parts will be omitted.

FIG. 14 is a diagram showing the k space in which the magnetic resonance signals 30 are acquired when performing the mask scan MS in the third embodiment of the invention,

In the present embodiment, as shown in Fig. 14, a three-dimensional k-space ks defined by three axes, a kx axis, a ky axis, and a kz axis is divided into segments symmetrical to the center of a kz-ky plane defined by the ky-axis and the kz-axis in the three-dimensional k-space ks. The mask scan MS is performed in such a way that the directions DR of acquiring the magnetic resonance signals every repetition time TR as mask data in the -23 segments which have divided the k-space ks, in opposite directions, by the directions are directed in the middle of the k-space. As shown in FIG. 14, the mask scan MS is performed here in such a way that the acquisition directions DR are directed to the circumference of the k-space ks, as seen from the center thereof.

Using mask data acquired by performing mask scan MS in this manner, difference images SG are generated in a manner similar to that of the first embodiment.

Since in the above-described present embodiment the mask scan MS is performed in a manner similar to that of the first embodiment, the image quality can be improved and an efficient execution of an image diagnosis can be facilitated.

<Fourth embodiment>

A fourth embodiment of the invention will be described below.

The present embodiment differs from the first embodiment in terms of a method for acquiring magnetic resonance signals in a k-space ks when performing a mask scan MS. Subject to this point, the present embodiment is similar to the first embodiment. Therefore, the description of equal parts will be omitted.

FIG. 15 is a diagram showing a sequence at the time mask data is acquired with respect to matrices forming respective segments when performing a mask scan MS in the fourth embodiment of the invention.

As shown in FIG. 15, when performing the mask scan MS in the present embodiment, scans are performed in such a way that magnetic resonance signals corresponding to a segment area A1 are acquired in a k space ks in a manner similar to that of the first embodiment. Here, a spatial saturation pulse SAT is sent to an area containing a fluid flowing in an imaging area. Thereafter, for example, a pulse sequence GR corresponding to the first gradient echo method is performed sequentially every repetition time TR. In contrast to the first embodiment of the invention, no mask data is acquired during a predetermined repetition time TR from the transmission of the spatial saturation pulse SAT. This means that a so-called dummy acquisition is performed a predetermined number of times. Thereafter, the magnetic resonance signals are acquired sequentially every mask repeat time TR as mask data.

Subsequently, scans are evenly performed on other segment areas A2, A3, A4, B1, B2, B3, B4, C1, C2, C3, C4, D1, D2, D3 and D4 to acquire mask data.

-24-

Using mask data acquired by performing the mask scan MS in this manner, difference images SG are generated in a manner similar to that of the first embodiment.

Thus, since the mask scan MS is performed in a manner similar to that of the first embodiment, the present embodiment is capable of improving image quality and facilitating efficient performance of an image diagnosis. Furthermore, when performing the mask scan MS in the present embodiment, the magnetic resonance signals are sequentially acquired as mask data after the repetition time TR, which is free from acquisition of the magnetic resonance signals as mask data, after the transmission of the spatial saturation pulse SAT, in contrast to the first embodiment. Since each signal is disturbed due to the application of the spatial saturation pulse SAT, the image quality deteriorates when the signal is obtained in the center of the k space ks. Since the dummy acquisition is performed and the mask data is acquired after stabilization of each signal, the present embodiment, on the other hand, can provide a further improvement in image quality.

<Fifth embodiment »

A fifth embodiment of the invention will be explained below.

The present embodiment differs from the fourth embodiment in terms of a method for acquiring magnetic resonance signals in a k-space ks when performing a mask scan MS. Subject to this point, the present embodiment is similar to the first embodiment. Therefore, the description of equal parts will be omitted.

FIG. 16 is a diagram showing a sequence at the time when mask data is acquired with respect to matrices forming segments when performing the mask scan MS in the fifth embodiment of the invention.

In performing the mask scan MS in the present embodiment, as shown in FIG. 16, a spatial saturation pulse SAT is sent to a fluid containing area flowing into an imaging area. Thereafter, for example, a pulse sequence GR corresponding to the first gradient echo method is performed sequentially every repetition time TR. Here, a dummy acquisition in which no mask data is acquired during a predetermined repetition time TR from the transmission of the spatial saturation pulse SAT is performed a predetermined number of times.

Thereafter, magnetic resonance signals corresponding to a segment area A1 in a k-space ks are acquired sequentially each repetition time TR as mask data. Here, magnetic resonance signals are sequentially acquired as mask data to correspond to a number of matrices arranged from a first matrix located in the center of the k space ks to a 125th matrix located at the periphery thereof , to correspond. A spatial saturation pulse SAT is then sent. Subsequently, magnetic resonance signals are sequentially acquired as mask data to correspond to a number of matrices from a 126th matrix located in the center of the k-space ks to a 128th matrix located at its periphery.

Thereafter, scans are performed sequentially even on other segment areas A2, A3, A4, B1, B2, B3, B4, C1, C2, C3, C4, D1, D2, D3 and D4 in a manner similar to that of the first segment area A1 to to acquire mask data.

Using the mask data acquired by performing the mask scan MS in this manner, difference images SG are generated in a manner similar to that of the first embodiment.

In contrast to the fourth embodiment, in performing the mask scan in the present embodiment described above, spatial saturation pulses SAT are sent during sequential acquisition of the mask data relating to the number of matrices that form segments, without transmitting the spatial saturation pulses SAT prior to the sequential acquisition of the mask data with respect to the number of matrices that form the segments. That is, each spatial saturation pulse SAT is transmitted in the course of the segments in the present embodiment.

Since each signal is disturbed due to the application of the spatial saturation pulse SAT, the image quality deteriorates when the signal is obtained in the center of the k-space ks. Although the spatial saturation pulse SAT is applied to the beginning of the segments and the dummy acquisition is performed to thereby stabilize each signal in the center of the k space in the fourth embodiment, an imaging time also increases with an increase in dummy acquisition. As in the present embodiment, the dummy acquisition or the process of acquiring mask data corresponding to an area located on the outside of the k space is performed during a period up to the acquisition of the mask data at the center of the k space, the number of dummy acquisitions performed as a whole being reduced in addition to the fact that acquisitions of the same number as in the fourth embodiment are performed from the application of the spatial saturation pulse SAT to the acquisition in the middle of the k space whereby it is possible to obtain any stable signal from the center of the k-space ks and to suppress extension of the display time. Incidentally, dummy pulses can be added after the spatial saturation pulses SAT applied to all segments of Fig. 16 to stabilize any signal obtained immediately after the application of each spatial saturation pulse SAT.

-26-

Incidentally, the magnetic resonance imaging device 1 according to the above embodiment is equivalent to a magnetic resonance imaging device of the invention. The scan section 2 of the present embodiment corresponds to a scan section of the invention.

In carrying out the invention, the invention is not limited to the above embodiments. Various modifications can be made.

The invention can be adapted when performing imaging in a two-dimensional area.

Although the k spaces in which the magnetic resonance signals are acquired in the mask scan MS and the image scan IS are respectively divided into the multiple segments by the various methods, the numbers of distributions thereof are random.

Although a description has been given of the case where the difference processing is performed on the mask image MG and the image image IG after the generation of the mask image MG and the image image IG, to thereby generate the difference image SG, the invention is not for this purpose limited. For example, difference processing is performed on mask data acquired by performing a mask scan and by performing a image scan IS acquired image data to thereby calculate difference data. Thereafter, image reconstruction processing can be performed on the difference data, so that the difference image SG is generated.

Although a description has been given of the case in which each spatial saturation pulse is transmitted, the invention can be applied to a case in which a different preparation pulse is transmitted instead of the spatial saturation pulse.

The spatial saturation pulses can be selectively supplied to slice areas or can be supplied non-selectively thereto. When the spatial saturation pulses are selectively applied, they may be applied to areas other than the image areas or may be applied to the image area to partially or completely overlap.

Many widely different embodiments of the invention can be formed without departing from the spirit and scope of the invention. It will be understood that the present invention is not limited to the specific embodiments described in the specification, except as defined in the appended claims.

-27- PART LIST Fig. 1 22 HF control unit 23 gradient control unit 24 data acquisition unit 30 control unit 31 image reconstruction unit 32 control unit 33 display unit 34 storage unit

FIG. 2 201 start S11 perform mask scan MS S21 perform image scan IS S31 generate image 202 end

FIG. 6 60 k space: inside 62 outside 64 segment area

FIG. 9 901 start

S311 generate mask image MG

S321 generate image image IG

S331 generate difference image SG

902 end

FIG. 15 150 k space: inside 152 outside 154 segment area 156 dummy -28-

FIG. 16 160 k space: inside 162 outside 164 segment area 166 dummy 2001360

Claims (10)

A magnetic resonance imaging device (1) which performs a mask scan for acquiring magnetic resonance signals produced as a mask data in an imaging area in which a fluid flows through a subject (SU) in a state in which no contrast medium is present in the image fluid is injected, and performs an imaging scan for acquiring magnetic resonance signals produced as imaging data in the imaging area, into which the contrast-containing fluid flows after the contrast agent injection into the fluid, to correspond to a TRICKS method, thereby sequentially generating images of the imaging area along a time base, which magnetic resonance imaging device (1) comprises: a scanning device (2) which performs the mask scan and the imaging scan, wherein the scanning device (2) performs of the mask scan repeatedly performs scans for h transmitting a spatial saturation pulse to a corresponding region containing the fluid flowing in the imaging region, and subsequently sequentially acquiring the magnetic resonance signals as mask data every mask repetition time, to correspond to respective segments, which in multiple form in a k space are divided. 2. Magnetic resonance imaging device (1) according to claim 1, wherein the scanning device (2) performs the mask scan in such a way that the directions of each repetition time sequentially acquire mask data of the magnetic resonance signals with respect to the respective segments in opposite directions passing through the center of the k space in the segments. 3. Magnetic resonance imaging device (1) according to claim 2, wherein the scanning device (2) performs the mask scan in such a way that the acquisition directions are directed from the center of the k space to the periphery thereof. A magnetic resonance imaging device (1) according to any of claims 1 to 3, wherein the scanning device (2), after transmitting the spatial saturation pulse, further performs the mask scan to sequentially acquire the magnetic resonance signals as mask data after the lapse each repetition time of each repetition time, which is free from acquisition of the magnetic resonance signals as mask data. A magnetic resonance imaging device (1) according to any of claims 1 to 4, wherein the scanning device (2), when performing the mask scan, performs the scans in such a way that they correspond to respective multi-segmented segments so as to be symmetrical to of an axis passing through the center of a 35 k space. -30- A magnetic resonance imaging device (1) according to any of claims 1 to 4, wherein the scanning device (2), when performing the mask scan, performs the scans in such a way that they correspond to respective multi-segmented segments in order to radially symmetrically the center of a k space to its circumference. The magnetic resonance imaging device (1) according to any of claims 1 to 6, wherein the scanning device (2) performs the mask scan prior to performing the imaging scan. 8. A magnetic resonance imaging method that performs a mask scan for acquiring, as mask data, magnetic resonance signals produced in an imaging area in which a fluid flows through a subject (SU) in a state in which there is no contrast agent in the fluid. is injected, and performs an imaging scan for acquiring magnetic resonance signals produced as imaging data in the imaging area, into which the contrast-containing fluid 15 flows after the contrast agent injection into the fluid, to correspond to a TRICKS method to thereby sequentially generate images of the imaging region along a time base, which magnetic resonance imaging method comprises a step of: repeatedly performing scans for performing a spatial saturation pulse to a corresponding region when performing the mask scan,the fluid flowing in the imaging area, and subsequently sequentially acquiring the magnetic resonance signals as mask data for each repetition time, to correspond to respective segments, which are divided into a k space in multiple form. A magnetic resonance imaging device (1) which performs a mask scan for acquiring magnetic resonance signals produced as a mask data in an imaging area of a subject (SU), and which performs an imaging scan for acquiring magnetic resonance signals as imaging data , produced in the imaging area, to correspond to a TRICKS method, thereby sequentially generating images of the imaging area along a time base, which magnetic resonance imaging device (1) comprises: a scanning device (2) which performs a mask scan and the imaging scan, in which the scanning device (2) repeatedly performs scans for performing a preparation pulse to the subject (SU) and subsequently sequentially acquiring the magnetic resonance signals as mask data each sequential time to correspond with respective in m simple form segments divided into a k-space. -31 - A magnetic resonance imaging method that performs a mask scan for acquiring magnetic resonance signals produced as a mask data in an imaging area of a subject (SU) and performing an imaging scan for acquiring magnetic resonance signals as imaging data, which are produced in the imaging area to correspond to a TRICKS method, thereby sequentially generating images of the imaging area along a time base, which magnetic resonance imaging method comprises the step of repeatedly performing the mask scan when performing the mask scan scans for sending a preparation pulse to the subject (SU) and thereafter sequentially acquiring the magnetic resonance signals as mask data to correspond to respective k-space divided segments in multiple form. 2001360 '